Detachable crawler

ABSTRACT

A detachable crawler ( 1, 20 ) capable of increasing the durability thereof on a rubber belt part ( 4 ) body side, wherein each of a metal core ( 6 ) and a track shoe ( 21 ) of a detachable pad ( 5 ) is formed so that tightening force in a specific range (approx. 4.90 to 78.5 MPa per unit area) can be applied to a rubber elastic body ( 4   a ) including a tensile reinforcing layer ( 2 ) sandwiched between a core bar ( 3 ) in the rubber belt part ( 4 ) and the metal core ( 6 ) or steel track shoe ( 21 ) of the detachable pad ( 5 ).

FIELD OF THE INVENTION

[0001] The present invention relates to a crawler for being used and installed to an endless track travel device driving agricultural work cars, civil engineering working machines or construction machines.

BACKGROUND OF THE INVENTION

[0002] Iron crawlers, rubber crawlers and connecting link rubber crawlers have long been used as an endless track travel device for driving construction machines.

[0003] A conventional iron crawler is so constructed that steel track shoes are fitted to an endless connecting link pivotally connecting a pair of track links with pins (by welding or bolt/nut mechanism). In this case, since mechanical connecting force between the track links is large, the iron crawler excels in durability. Besides, when a track shoe is abraded, it is exchangeable. However, the iron crawler has such troubles as large creaky noise due to the track links and driver's fatigue due to scanty cushion performance. Besides, if the iron crawler drives on pavements in urban areas, the road surface is damaged.

[0004] Besides, a conventional rubber crawler is so constructed that metal core bars and steel cords serving as a tensile reinforcing layer are embedded in a rubber elastic body. In this case, there is little noise, cushion performance is good, and the road surface is not damaged. Besides, since the rubber crawler is comparative lightweight, it can drive speedily. However, when the rubber crawler drives on keen rocks or engineering wastes, cut flaws sometimes happen in a rubber part. When some cut flaws get to any steel cords of the rubber crawler, the steel cords divide due to cutting or corrosion. Therefore, the rubber crawler is unserviceable whether the rubber part is still available or not. Besides, when a tread lug rubber part is abraded by friction with the road surface, the whole rubber crawler must be integrally exchanged.

[0005] Recently, there is a connecting link rubber crawler as a crawler for making good use of each merit of the conventional iron crawler and rubber crawler and for making up for each fault thereof. The conventional connecting link rubber crawler is so constructed that rubber pads (divided type or continuous type) are fitted to an endless connecting link pivotally connecting a pair of track links with pins (by welding or bolt/nut mechanism). Here, a rubber pad is so made that a rubber elastic body is molded and fixed to a metal core. The connecting link rubber crawler has some merit as shown below. That is, since the mechanical connecting force between the track links is large, the connecting link rubber crawler excels in durability. When the tread lug rubber part of the rubber pad is abraded, the only rubber pad can be exchanged. Besides, the road surface is not damaged. However, since the connecting link rubber crawler uses connecting links composed of track links, the noise is large. Accordingly, since night engineering works are increased in the urban areas recently, there is still an important noise problem in the connecting link rubber crawler.

[0006] Moreover, a detachable rubber crawler is disclosed in Japanese Patent Provisional Publication No. 133876 of 1992. The detachable rubber crawler is provided with tread lug rubber parts to be exchanged when they are abraded or lacking, or when their lug shape are changed in accordance with soil property. The detachable rubber crawler, as shown in FIG. 19 and FIG. 20, comprises lug rubber parts 22 of one to two or more independent joint articles (which are detachable rubber pads) and a rubber belt part 26. The rubber belt part 26 is arranged to a crawler anti-tread (driving wheel) side with a tensile reinforcing layer 24 and core bars 25 embedded in a rubber elastic body 23. A lug rubber part 22 is provided with a steel metal core 27 and two or more steel pipes 29 each having a hole through which a bolt 28 for fastening the rubber belt part 26 welded to the metal core 27 is passed. A core bar 25 embedded in the rubber belt part 26 is provided with two or more holes with a fixed depth necessary for the steel pipes 29 and holes necessary for the bolts 28 on the same axis therewith. Here, in drawings, 30 is a nut, and 31 is a washer.

[0007] In the above-mentioned detachable rubber crawler, when the lug rubber parts are abraded or lacked, they can be exchanged. Besides, since the detachable rubber crawler uses not connecting links but a rubber belt part, noise problem can be settled.

[0008] However, as for the rubber belt part, when a large driving force is added to the rubber crawler, a large shear force acts between the core bar and the steel cords like the conventional rubber crawler. When the large shear force acts repeatedly, the bonded portion between the core bar and the steel cords gradually causes a fatigue failure. Therefore, since the rubber belt part damages in durability, the detachable rubber crawler can not completely make good use of an advantage of the exchangeable lug rubber part.

SUMMARY OF THE INVENTION

[0009] The present invention aims to settle the above-mentioned problems. In the present invention, a crawler comprises detachable pads of one to two or more independent joint articles and a rubber belt part arranged to a crawler anti-tread (driving wheel) side with a tensile reinforcing layer and core bars embedded in a rubber elastic body. And therein, the detachable pads are detachably fitted to the rubber belt part, thereby forming a detachable crawler capable of exchanging them. Here, the rubber elastic body having the tensile reinforcing layer is sandwiched and presssed between the core bars and metal cores or steel track shoes of the detachable pads, thereby affecting enforcing pressure in a fixed range. Therefore, the rubber belt part increases in durability and in a unit-area drawing shear stress between the rubber elastic body and the tensile reinforcing layer, thereby enabling the detachable crawler to prevent noise and to improve in durability in addition to its convenience.

[0010] In this case, in the rubber belt part, the tensile reinforcing layer is so formed that two or more tensile reinforcing members are arranged and embedded in the rubber elastic body in parallel rows to a crawler width direction along a crawler circumference direction, and the core bars are embedded therein at a fixed interval along the crawler circumference direction. Besides, the detachable pads are exchangeably fitted to a tread side of the rubber belt part by fastening fixtures. In this case, the rubber elastic body including the tensile reinforcing layer sandwiched between the metal cores or the steel track shoes of the detachable pads and the core bars in the rubber belt part is pressed by tightening the fastening fixtures.

[0011] Besides, the present invention is characterized in which the above-mentioned tightening force is made in a specific range, namely, 4.90 to 78.5 MPa (50 to 800 kgf/cm²), preferably 7.85 to 58.8 MPa (80 to 600 kgf/cm²), more preferably 7.85 to 39.23 MPa (80 to 400 kgf/cm²) per unit area of the rubber elastic body including the tensile reinforcing layer.

[0012] A graph in FIG. 18 shows a relation of tightening force and shear drawing strength. That is, it shows a relation of tightening force per unit area (Pa) for pressing the steel cords and the rubber elastic body, and shear-drawing strength per unit area (MPa) between the steel cords and the rubber elastic body.

[0013] In the graph, a line A shows an example that the steel cords and the rubber elastic body are molded and fixed. The shear strength is 7.85 MPa (80 kgf/cm²) when the steel cords and the rubber elastic body are not pressed, whereas it increases in 10.59 MPa (108 kgf/cm²) when they are pressed by 9.81 MPa (100 kgf/cm²) tightening force.

[0014] A line B shows an example that the steel cords and the rubber elastic body are not molded and fixed. Though the shear strength is naturally 0.00 MPa when they are not pressed, it is 10.40 MPa (106 kgf/cm²) when they are pressed by 9.81 MPa (100 kgf/cm²) tightening force. Accordingly, tightening operation increases the shear strength of 0.00 MPa at first in more than 7.85 MPa (80 kgf/cm²) corresponded to the shear strength that the rubber elastic body are molded and fixed to the steel cords.

[0015] Accordingly, since a fixing layer between the steel cords and the rubber elastic body is not fatigued, the shear strength therebetween is not reduced but kept suitably. Therefore, the rubber belt part increases in durability.

[0016] Though a steel cord is usually used as a tensile reinforcing member, high-strength synthetic fibers can be also used. The tensile reinforcing member is not limited particularly.

[0017] Though a bolt and a nut mainly are used as a fastening fixture, a wedge system or another system can be also used. It may be what the pads are suitably fitted or removed to the rubber belt part and they are pressed with necessary tightening force.

[0018] Each of the detachable pads may be a continuous pad in the crawler width direction with a size corresponding to a core bar embedded in the rubber belt part. Besides, it may be one divided into right and left in the crawler width direction. Moreover, it may be in a size over two adjacent core bars in the crawler circumference direction, or over three core bars.

[0019] When each of the detachable pads is divided into right and left in the crawler width direction with a size over two or three core bars, the divided pads may be shifted in the crawler circumferential direction what we call in a staggered arrangement. Naturally, they may be arranged to the same position on both sides.

[0020] The detachable pads may be one or two or more joint articles that are independent respectively. Besides, an iron pad of a steel track shoe, a rubber pad that a rubber elastic body is molded and fixed to a metal core, or a resin pad that urethane, thermoplastic or thermosetting resin, or plastic is fixed to a metal core may be used as the pad part. Similarly, urethane, thermoplastic or thermosetting resin, or plastic may be used as the rubber elastic body of the rubber belt part.

BRIEF DESCRIPTION OF THE DRAWINGS

[0021]FIG. 1 is a plan view showing an anti tread side of a detachable rubber crawler of the first embodiment. FIG. 2 is a plan view showing a tread side of the detachable rubber crawler of the first embodiment. FIG. 3 is a section view taken on line X-X in FIG. 1, and FIG. 4 is a section view taken on line Y-Y in FIG. 1.

[0022]FIG. 5A is a section view explaining a situation that a detachable pad (rubber pad) of the detachable rubber crawler of the first embodiment is fitted to a rubber belt part, and FIG. 5B is a grossly enlarged section view of an important part in FIG. 5A.

[0023]FIG. 6A is a plan view showing a tread side of the detachable pad (rubber pad) of the detachable rubber crawler of the first embodiment, FIG. 6B is a plan view showing an anti tread side of the rubber pad, and FIG. 6C is a side view of the detachable pad (rubber pad).

[0024]FIG. 7A is a section view showing an alternate example 1 of the first embodiment, FIG. 7B is a section view showing an alternate example 2, and FIG. 7C is a section view showing an alternate example 3.

[0025]FIG. 8A is a side section view showing the first embodiment, and FIG. 8B is a side section view showing an alternate example 4 of the first embodiment.

[0026]FIG. 9 is a plan view showing a tread side of a detachable rubber crawler of the second embodiment, FIG. 10 is a section view taken on line X-X in FIG. 9, and FIG. 11 is a section view taken on line Y-Y in FIG. 9.

[0027]FIG. 12 is a plan view showing a tread side of a detachable rubber crawler of the third embodiment, FIG. 13 is a section view taken on line X-X in FIG. 12, and FIG. 14 is a section view taken on line Y-Y in FIG. 12.

[0028]FIG. 15A is a section view showing an alternate example 1 of a fastening fixture of a fitting member, FIG. 15B is a section view showing an alternate example 2 thereof, and FIG. 15C is a partial section view showing an alternate example 3 thereof.

[0029]FIG. 16 is a section view in a crawler width direction showing a detachable iron crawler of the fourth embodiment, and FIG. 17 is a section view of showing an important part of an alternate example thereof.

[0030]FIG. 18 is a graph showing a relation of tightening force per unit area (MPa) for pressing steel cords and a rubber elastic body, and a shear drawing strength per unit area (MPa) therebetween.

[0031]FIG. 19A is a perspective view of a conventional detachable rubber crawler, and FIG. 19B is a plan view of the anti tread side thereof.

[0032]FIG. 20A is a side view of the conventional detachable rubber crawler and FIG. 20B is a plan view of the tread side thereof. FIG. 20C is a section view taken on line A-A in FIG. 19B, and FIG. 20D is a detailed section view of a fitting part of a rubber belt part and a detachable rubber pad.

PREFERRED EMBODIMENT OF THE INVENTION

[0033] Embodiments in the present invention will be explained in detail with reference to the drawings. FIGS. 1 to 6 show a detachable rubber crawler 1 of the first embodiment of a detachable crawler. FIG. 1 is a plan view showing an anti tread side (inside periphery side) of the detachable rubber crawler 1 of the first embodiment. FIG. 2 is a plan view showing a tread side (outside periphery side) thereof, FIG. 3 is a section view taken on line X-X in FIG. 1, and FIG. 4 is a section view taken on line Y-Y in FIG. 1. FIG. 5A is a section view explaining a situation that a rubber pad 5 of the detachable rubber crawler 1 of the first embodiment is fitted to a rubber belt part 4, and FIG. 5B is a grossly enlarged section view of an important part in FIG. 5A. FIG. 6A is a plan view showing a tread side (outside periphery side) of the rubber pad 5 of the detachable rubber crawler 1 of the first embodiment, FIG. 6B is a plan view showing an anti tread side (inside periphery side) of the rubber pad 5, and FIG. 6C is a side view of the rubber pad 5.

[0034] As for the detachable rubber crawler 1, two or more steel cords 2 serving as a tensile reinforcing layer are arranged and embedded in a rubber elastic body in parallel rows to a crawler width direction along a crawler circumference direction. Besides, a rubber belt part 4 is so formed that core bars 3 are embedded at a fixed interval in the crawler circumference direction, and the rubber pads 5 are detachably fitted to the tread side of the rubber belt part 4 removably, namely exchangeably.

[0035] A rubber pad 5 is integrally formed by molding and fixing a rubber elastic body to a metal core 6. Besides, the metal core 6 is provided with protrusions 7 to right and left sides of a longitudinal direction of the anti tread side, and the protrusions 7 are provided with thread holes 9 each grooved female screw to be interfitted bolts 8 into. Here, each of the bolts 8 serves as a fastening fixture.

[0036] On the other hand, the rubber belt part 4 is provided with concave parts 10 to the tread side of the core bars 3 whose positions correspond to the protrusions 7. The concave parts 10 are formed so as to get to the core bars 3 so that the protrusions 7 are interfitted therein. The concave parts 10 have through holes 11 passing from the anti tread side of the rubber belt part 4 to the tread side thereof so that the bolts 8 are fitly inserted therein. Besides, the rubber belt part 4 is provided with interfitted holes 12 to the tread side so that the protrusions 7 are inserted therein.

[0037] The rubber pads 5 are removably fitted to the rubber belt part 4 by interfitting the protrusions 7 to the interfitted holes 12 and the concave parts 10, inserting the bolts 8 into the through holes 11, and tightening the bolts 8 to the thread holes 9.

[0038] In this case, a bolt 8 is tightened by torque of 136 N·m (13.86 kgf·m) so that a rubber elastic body 4 a including a layer of steel cords 2 sandwiched between the metal core 6 of the rubber pad 5 and the core bar 3 of the rubber belt part 4 is pressed by tightening force 9.81 MPa per unit area (100 kgf/cm²). (In this embodiment, M14 bolts are used, and the torque coefficient is 0.02. Besides, since gross tightening area per a core bar 3 (a metal core 6) is 1980 mm², a tightening area per a bolt is 1980/4=495 mm².)

[0039] Besides, in drawings, 13 is a hole for discharging mud, and 14 is a tool hole in which a tool (socket wrench) for tightening a bolt is inserted.

[0040] In this embodiment, the concave parts 10 and the protrusions 7 are respectively provided on right and left sides divided from the center of the crawler width direction, and besides, arranged to the around center of each side. The layer of steel cords is divided and embedded in right and left sides from the center of the crawler width direction, and besides, still more divided and embedded in each side by the concave part 10 and the protrusion 7. Here, the rubber elastic body including the layer of steel cords is surrounded by the core bar 3 of the rubber belt part 4, the metal core 6 of the rubber pad 5, and prevention walls 6 a provided to the both ends of the metal core 6 in the crawler width direction. Accordingly, even if the rubber elastic body is sandwiched and pressed by the core bar 3 and the metal core 6, the rubber elastic body is prevented from escaping (being pushed out) outside the crawler width direction, and therefore tightening force is surely added.

[0041] Besides, the protrusion 7 is shallowly interfitted in the concave part 10. Here, the height H1 of the protrusion 7 is lower than the depth H2 from the bottom of the interfitted hole 12 including the concave part 10 to the tread side of the rubber belt part 4, and higher than the depth H3 from the top of the tread side of the concave part 10 thereto.

[0042] When the height H1 is higher than the depth H2, the protrusion 7 is oppositely touched to the concave part 10 before the tightening force is added to the rubber elastic body 4 a including the layer of steel cords 2 sandwiched between the metal core 6 and the core bar 3. Therefore, even if the bolt is tightened firmly, the tightening force call not be added to the rubber elastic body 4 a. On the other hand, when the height H1 is lower than the depth H3, the protrusion 7 is not interfitted in the concave part 10, and loading is added to the bolt 8 so as to damage it. Therefore, the depth H2 of an interfitted hole is usually made deeper about 2 to 5 mm than the height H1 of a protrusion.

[0043] Besides, in the detachable rubber crawler 1 of this embodiment, the top of a guide protrusion of the core bar 3 forms a flat rolling contact surface 3 a, and each of the both ends of the crawler width direction thereof is provided with a step part 3 b serving as a rolling contact surface such as a wheel of outside wheel type can roll. According to this, the detachable crawler can be driven in a wheel of any type such as inside wheel or outside wheel of exclusive type or inside collar wheel or outside collar wheel of exchangeable type.

[0044] Next, an alternate example about a concave part 10 and a protrusion 7 for fitting the rubber pad 5 to the rubber belt part 4 in the first embodiment will be explained in reference with FIGS. 7 and 8.

[0045] In FIG. 7A, a concave part 10 and a protrusion 7 for fitting the rubber pad 5 to the rubber belt part 4 are positioned at the both ends of the crawler width direction.

[0046] In FIG. 7B, a concave part 10 and a protrusion 7 for fitting the rubber pad 5 to the rubber belt part 4 are positioned at the both ends of the guide protrusion in the crawler width direction. Besides, in this embodiment, a core bar 3 has no step parts 3 b.

[0047] In FIG. 7C, concave parts 10 and protrusions 7 are added to the both ends of the guide protrusion in the crawler width direction, the rubber pad 5 and the rubber belt part 4 are fitted at eight positions.

[0048] In FIG. 8B, the numbers of concave parts 10 and protrusions 7 for fitting the rubber pad 5 to the rubber belt part 4 are respectively decreased in from 4 to 2. In the first embodiment shown in FIG. 8A, there are two fitting parts in the core bar 3 at front and rear from the sight of crawler circumference direction, whereas there is one fitting part in the embodiment shown in FIG. 813.

[0049] Though the shapes of the concave part 10 and the protrusion 7 are respectively defined to complete round in drawings, they may be rectangle or ellipse by connecting two protrusions 7 and two concave parts 10 provided to the front and rear positions of the crawler circumference direction respectively. In this case, since the same effect can be gained as by the prevention wall 6 a, the prevention wall 6 a needs not to be provided.

[0050] FIGS. 9 to 11 show a detachable rubber crawler 1 of the second embodiment in the invention. FIG. 9 is a plan view showing the tread side (outside periphery side) of the detachable rubber crawler 1, FIG. 10 is a section view taken on line X-X, and FIG. 11 is a section view taken on line Y-Y.

[0051] As for the detachable rubber crawler 1 of the second embodiment, a rubber pad 5 is the same size as a lug rubber part crossing two adjacent core bars 3 in the rubber belt 4. According to this, the lug rubber part of the rubber pad 5 can be enlarged, thereby improving in durability.

[0052] Besides, the rubber pad 5 has a hole 13 for discharging mud at the center of the crawler width direction, and the portion sandwiched between the engaging holes serves as an inside lug 15 with height low one step.

[0053] Next, a detachable rubber crawler 1 of the third embodiment in the invention will be explained in reference with FIGS. 12 to 14.

[0054] As for the detachable rubber crawler 1 of the third embodiment, the rubber pad 5 in the second embodiment is divided into right and left from the center of the crawler width direction, and the divided right and left rubber pads 5 are shifted to front and rear of the circumference direction in the crawler width direction, namely, arranged in staggered shape.

[0055] According to this, the rubber lug parts are arranged to the whole in front and rear of the crawler circumference direction. That is, the lug rubber part of the rubber pad 5 exists in either of right and left sides in the crawler width direction at the portion with the low rigidity between the adjacent core bars 3 embedded in the rubber belt part 4. According to this, the rigidity of the crawler is uniformed, thereby preventing the crawler from getting out of the travel device, and the stress from concentrating to the rubber belt part 4 with the core bar 3 not embedded. Accordingly, the detachable rubber crawler 1 can be made good in the elasticity.

[0056] Besides, an inside lug 15 is integrally molded by one place to the rubber pads 5 arranged on both sides of the crawler width direction, and besides, arranged before and behind the hole 13 in the crawler circumference direction.

[0057] A pin 16 is protrusively provided to the center of the core bar 3 embedded in the rubber belt part 4 toward the tread side. The pin 16 is interfitted into a pin hole 17 provided to the metal core 6 of the rubber pad 5, thereby preventing the rubber pad 5 from shifting longitudinally or laterally.

[0058] In the second and the third embodiments, though the rubber pads 5 are the size as the lug rubber parts crossing the two adjacent core bars 3 in the rubber belt 4, they may be the same size as one crossing three core bars 3 or over.

[0059] Next, an alternate example about a fastening fixture of a fitting member in the above-mentioned embodiments will be explained in reference with FIG. 15.

[0060] In the embodiment shown in FIG. 15A, a thread part of a bolt is integrally molded to the protrusion 7 of the rubber pad 5, thus and so, a male thread part 7 a is provided to the protrusion 7. The male thread part 7 a and the protrusion 7 are interfitted into the rubber belt part 4, and a nut 18 is tightened to the male thread part 7 a protrudently passing therethrough. Thus and so, the rubber pad 5 is fitted to the rubber belt part 4, and the rubber elastic body including the layer of steel cords 2 sandwiched between the metal core 6 in the rubber pad 5 and the core bar 3 in the rubber belt part 4 is pressed.

[0061] In the embodiment shown in FIG. 15B, a tool hole 14 is provided to the rubber elastic body of the rubber pad 5. A bolt 8 is interfitted therein from the tread side of the rubber pad 5 toward the metal core 6 of the anti tread side, or a tool for fastening bolts (a socket wrench etc.) is interfitted therein. Besides, a through hole 11 is provided to the protrusion 7 of the metal core 6, the bolt 8 is inserted therein from the tread side of the rubber pad 5, and a nut 18 is tightened to the male thread of the bolt 8 protruding from the opposite rubber belt part 4. Thus and so, the rubber pad 5 is fitted to the rubber belt part 4, and the rubber elastic body including the layer of steel cords 2 sandwiched between the metal core 6 and the core bar 3 is pressed. Besides, in this case, the bolt 8 may be inserted from the anti tread side of the rubber belt part 4, and the nut 18 may be tightened from the tread side of the rubber pad 5.

[0062] In the embodiment shown in FIG. 15C, there is not formed any protrusion to a metal core 6 differently from the above-mentioned embodiment. That is, in this embodiment, a female thread 19 is provided to the metal core 6 in the rubber pad 5, and screwed to the bolt 8 inserted from the anti tread side of the core bar 3. Then, the rubber elastic body including the layer of steel cords 2 sandwiched between the core bar 3 and the metal core 6 is similarly pressed by such a rotational motion.

[0063]FIG. 16 is a section view in the crawler width direction, which shows a detachable iron crawler 20 of the fourth embodiment of a detachable crawler.

[0064] In the detachable iron crawler 20 of the fourth embodiment, a steel track shoe 21 is fitted to the rubber belt part 4 instead of each rubber pad 5 in the above-mentioned embodiments. The detachable iron crawler 20 is composed like the above-mentioned embodiments, and so formed that the steel track shoe 21 is pressed to the rubber elastic body including the layer of steel cords 2 sandwiched with the core bar 3 in the rubber belt 4 at fixed force by tightening the bolt 8.

[0065]FIG. 17 is a section view of an important part showing an alternate example of the above-mentioned embodiment, and therein, the top of a guide protrusion of a core bar 3 is not a flat rolling contact surface 3 a but a pointed protrusion 3 c.

[0066] The invention is not restricted to the above-mentioned embodiments, and it is possible to combine these embodiments suitably.

[0067] In the invention, a crawler comprises detachable pads composed of from one to two or more independent joint articles and a rubber belt part arranged to a crawler anti tread (driving wheel) side into which a tensile reinforcing layer and core bars are embedded. And therein, the detachable pads are removably fitted to the rubber belt part, and can be exchanged. In this case, the detachable pads are fitted to the rubber belt part so that a metal core or a track shoe in a detachable pad and a core bar in the rubber belt part are connected by tightening fastening fixtures. And tightening force certainly acts on the rubber elastic body and the tensile reinforcing layer sandwiched between the metal core or the track shoe in the detachable pad and the core bar in the rubber crawler in a specific range. Therefore, the detachable crawler increases in a unit-area drawing shear stress between the rubber elastic body and the tensile reinforcing layer of the rubber belt part. Besides, since the rubber belt part increases in durability, the detachable crawler can prevent from noise and improve in durability in addition to the convenience. 

1. A detachable crawler comprising: a rubber belt part (4), said rubber belt part comprising a rubber elastic body (4 a), a tensile reinforcing layer (2) and core bars (3), said tensile reinforcing layer (2) comprising two or more tensile reinforcing members arranged and embedded in the rubber elastic body (4 a) in parallel rows to a crawler width direction along a crawler circumference direction, and said core bars being embedded therein at fixed intervals in the crawler circumference direction; and detachable pads, each of said detachable pads comprising a rubber pad (5) or an iron pad mountable and dismountable to a tread side of the rubber belt part (4) by fastening fixtures, said rubber pad (5) comprising a metal core (6) and a rubber elastic body, and said iron pad comprising a steel track shoe (21); wherein the rubber elastic body (4 a) including the tensile reinforcing layer sandwiched between each of the core bars (3) in the rubber belt part (4) and the metal core (6) or the steel track shoe (21) is pressed by tightening fastening fixtures (8, 18).
 2. A detachable crawler as claimed in claim 1, wherein tightening force of 4.90 to 78.5 MPa per unit area can be applied to a rubber elastic body (4 a) including a tensile reinforcing layer sandwiched between a core bar (3) of a rubber belt (4) and a metal core (6) or a steel track shoe (21) of a detachable pad.
 3. A detachable crawler as claimed in claim 1 or claim 2, wherein each of a metal core (6) and a steel track shoe (21) has prevention walls (6 a) in a fixed size to both ends of the crawler width direction to prevent a rubber elastic body (4 a) of a rubber belt part (4) side from escaping when fastening fixtures (8, 18) are tightened.
 4. A detachable crawler as claimed in claim 1, claim 2 or claim 3, wherein each of a metal core (6) and a steel track shoe (21) has protrusions (7) around both ends of the crawler width direction, and a rubber belt part (4) is provided with concave parts (10) for getting to a core bar (3) to portions corresponding to the protrusions (7), and each of the concave parts (10) has an interfitted hole (12) deeper than the height of each of the protrusions (7). 